Key Design Elements of a Radio-Acoustic-Sounding System for Industrial Applications

Dominik Exel; Stefan Schuster; Stefan Scheiblhofer; Dominik Zankl; Vera Ganglberger; Johann Reisinger; Bernhard Zagar

Key Design Elements of a Radio-Acoustic-Sounding System for Industrial Applications

Dominik Exel, Stefan Schuster, Stefan Scheiblhofer, Dominik Zankl, Vera Ganglberger, Johann Reisinger, Bernhard Zagar

Institute of Measurement Technology

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

This article discusses compact radio-acoustic-sounding systems (RASSs) for industrial applications. The electromagnetic-acoustic interaction enables to measure temperatures of gases without contact and spatially resolved. For this purpose, the speed of a modulated sound pulse, travelling through the gas with a velocity proportional to the temperature, is determined with a Doppler radar. The optimum sound pulse´s in terms of its frequency is discussed. The so called Bragg condition is essential to obtain sufficient receive power. The two most important conditions for an optimal Bragg reflection are the tuning of the wavelengths and an optimal collocation of the sources. These conditions are calculated numerically and verified with real-world measurement data. One purpose of this paper is to summarize physical effects that are key elements to the function of the RASS.

Original language	English
Title of host publication	Tagungsband 20. GMA/ITG-Fachtagung Sensoren und Messsysteme 2019
Editors	AMA Service GmbH
Pages	430 - 435
Number of pages	6
Publication status	Published - Jun 2019

Fields of science

202012 Electrical measurement technology
202036 Sensor systems
202027 Mechatronics
202037 Signal processing

JKU Focus areas

Digital Transformation

Cite this

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title = "Key Design Elements of a Radio-Acoustic-Sounding System for Industrial Applications",

abstract = "This article discusses compact radio-acoustic-sounding systems (RASSs) for industrial applications. The electromagnetic-acoustic interaction enables to measure temperatures of gases without contact and spatially resolved. For this purpose, the speed of a modulated sound pulse, travelling through the gas with a velocity proportional to the temperature, is determined with a Doppler radar. The optimum sound pulse´s in terms of its frequency is discussed. The so called Bragg condition is essential to obtain sufficient receive power. The two most important conditions for an optimal Bragg reflection are the tuning of the wavelengths and an optimal collocation of the sources. These conditions are calculated numerically and verified with real-world measurement data. One purpose of this paper is to summarize physical effects that are key elements to the function of the RASS.",

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year = "2019",

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T1 - Key Design Elements of a Radio-Acoustic-Sounding System for Industrial Applications

AU - Exel, Dominik

AU - Schuster, Stefan

AU - Scheiblhofer, Stefan

AU - Zankl, Dominik

AU - Ganglberger, Vera

AU - Reisinger, Johann

AU - Zagar, Bernhard

PY - 2019/6

Y1 - 2019/6

N2 - This article discusses compact radio-acoustic-sounding systems (RASSs) for industrial applications. The electromagnetic-acoustic interaction enables to measure temperatures of gases without contact and spatially resolved. For this purpose, the speed of a modulated sound pulse, travelling through the gas with a velocity proportional to the temperature, is determined with a Doppler radar. The optimum sound pulse´s in terms of its frequency is discussed. The so called Bragg condition is essential to obtain sufficient receive power. The two most important conditions for an optimal Bragg reflection are the tuning of the wavelengths and an optimal collocation of the sources. These conditions are calculated numerically and verified with real-world measurement data. One purpose of this paper is to summarize physical effects that are key elements to the function of the RASS.

AB - This article discusses compact radio-acoustic-sounding systems (RASSs) for industrial applications. The electromagnetic-acoustic interaction enables to measure temperatures of gases without contact and spatially resolved. For this purpose, the speed of a modulated sound pulse, travelling through the gas with a velocity proportional to the temperature, is determined with a Doppler radar. The optimum sound pulse´s in terms of its frequency is discussed. The so called Bragg condition is essential to obtain sufficient receive power. The two most important conditions for an optimal Bragg reflection are the tuning of the wavelengths and an optimal collocation of the sources. These conditions are calculated numerically and verified with real-world measurement data. One purpose of this paper is to summarize physical effects that are key elements to the function of the RASS.

UR - http://www.sensoren2019.de/

M3 - Conference proceedings

SN - 978-3-9819376-0-2

SP - 430

EP - 435

BT - Tagungsband 20. GMA/ITG-Fachtagung Sensoren und Messsysteme 2019

A2 - AMA Service GmbH, null

ER -

Key Design Elements of a Radio-Acoustic-Sounding System for Industrial Applications

Abstract

Fields of science

JKU Focus areas

Other files and links

Verfahren zur tomographischen Gichtgastemperatur- und Geschwindigkeitsmessung in einem Hochofen - Gicht: RASS - FFG 861570

Cite this

Key Design Elements of a Radio-Acoustic-Sounding System for Industrial Applications

Abstract

Fields of science

JKU Focus areas

Other files and links

Projects

Verfahren zur tomographischen Gichtgastemperatur- und Geschwindigkeitsmessung in einem Hochofen - Gicht: RASS - FFG 861570

Cite this